AU2022283749A1 - Device and method thereof for determining detonator information by using wireless signal - Google Patents

Abstract

A device and a method thereof for determining detonator information by using a wireless signal are proposed. The device includes an electromagnetic wave reception unit configured to receive an electromagnetic wave transmitted from a detonator in a blast hole, a coordinate derivation unit configured to detect the received electromagnetic wave and derive the electromagnetic wave as coordinates, a blast hole location determination unit configured to determine a location of the blast hole on the basis of a flickering pattern of the electromagnetic wave derived as the coordinates, and a detonator ID acquisition unit configured to acquire an ID of the detonator in the corresponding blast hole on the basis of the determined location of the blast hole.

Description

DESCRIPTION DEVICE AND METHOD THEREOF FOR DETERMINING DETONATOR INFORMATION BY USING WIRELESS SIGNAL

Technical Field

The present disclosure relates to a device and a method

thereof for determining detonator information by using a

wireless signal and, more particularly, to a device and a

method thereof for determining detonator information by using

a wireless signal, wherein an electromagnetic wave emitted

from a detonator in a blast hole is detected and derived as

coordinates, and a location of the blast hole and an ID of the

detonator in the blast hole are determined on the basis of a

flickering pattern of the electromagnetic wave derived as the

coordinates.

Background Art

In general, when single-face blasting work is performed,

after an electronic detonator is charged into a blast hole,

connectors should be aligned in a desired time-in-milliseconds

sequence when to connect to a trunk wire, and a code attached

to each connector or each wire should be read with a reading

device in the corresponding sequence when to obtain an ID. In

this case, when the sequence is wrong, the time-in milliseconds sequence is also changed, so there may occur cases where blasting efficiency is affected, and a cross section after blasting is poorly formed or follow-up work is required. In addition, when the blasted cross-section is large, an additional time is required because work at height should be performed aboard equipment to collect the ID.

Meanwhile, in another type of electronic detonator, a

time in milliseconds is assigned in advance or a time in

milliseconds is assigned on the spot before a detonator is

charged into a blast hole, so the electronic detonator has the

same method as that of the existing non-electric detonator.

However, in this case as well, the possibility of a work error

occurring due to human errors may not be ruled out.

As described above, in the case where the time in

milliseconds is assigned in advance, there is a difficulty in

logistics management, and in the case where the time in

milliseconds is assigned on the spot, there is a disadvantage

in that the possibility of work errors is high because of no

separate marking.

In this regard, Korean Patent Application Publication No.

2000-0061481 discloses "METHOD FOR DESIGNING TUNNEL-BLASTING

PATTERN DIAGRAM AND RECORDING MEDIUM WITH PROGRAM FOR PROVIDING TUNNEL-BLASTING PATTERN DIAGRAM".

Disclosure

Technical Problem

The present disclosure is devised to solve the above

problems, and an objective of the present disclosure is to

provide a device and a method thereof for determining

detonator information by using a wireless signal, wherein an

electromagnetic wave emitted from a detonator in a blast hole

is detected and derived as coordinates, and a location of the

blast hole and an ID of the detonator in the blast hole are

determined on the basis of a flickering pattern of the

electromagnetic wave derived as the coordinates.

In addition, another objective of the present disclosure

is to provide a device and a method thereof for determining

detonator information by using a wireless signal, wherein the

detonator information including a location of the determined

blast hole and an obtained ID of the detonator in the

corresponding blast hole is schematized and output to a

display means, and an input of setting information for setting

at least any one of a blasting sequence and a time in

milliseconds on the basis of the schematically output

detonator information is received and transmitted to blasting

equipment.

Technical Solution

According to the present disclosure for achieving the

above objectives, there is provided a device for determining detonator information by using a wireless signal, the device including: an electromagnetic wave reception unit configured to receive an electromagnetic wave transmitted from a detonator in a blast hole; a coordinate derivation unit configured to detect the received electromagnetic wave and derive the electromagnetic wave as coordinates; a blast hole location determination unit configured to determine a location of the blast hole on the basis of a flickering pattern of the electromagnetic wave derived as the coordinates; and a detonator ID acquisition unit configured to acquire an ID of the detonator in the corresponding blast hole on the basis of the determined location of the blast hole.

In addition, the electromagnetic wave reception unit may

receive the electromagnetic wave having the flickering pattern

including identification information of the detonator at the

location of the blast hole, the electromagnetic wave being

transmitted by the detonator in the blast hole after receiving

a command of blasting equipment.

In addition, the coordinate derivation unit may

recognize a transmission position and intensity according to

the flickering pattern of the electromagnetic wave received by

using an electromagnetic wave detection sensor, and derive the

transmission position and the intensity as x, y coordinates.

In addition, the device may further include an

information output unit configured to schematize the detonator information including the determined location of the blast hole and the acquired ID of the detonator in the corresponding blast hole, and output the schematized detonator information to a display means.

In addition, the device may further include a setting

information transmission unit configured to receive an input

of setting information for setting at least any one of a

blasting sequence and a time in milliseconds on the basis of

the schematically output detonator information, and transmit

the setting information to the blasting equipment.

According to the present disclosure for achieving the

above objectives, there is provided a method for determining

detonator information by using a wireless signal, the method

including: receiving, by an electromagnetic wave reception

unit, an electromagnetic wave transmitted from a detonator in

a blast hole; detecting, by a coordinate derivation unit, the

received electromagnetic wave and deriving the electromagnetic

wave as coordinates; determining, by a blast hole location

determination unit, a location of the blast hole on the basis

of a flickering pattern of the electromagnetic wave derived as

the coordinates; and acquiring, by a detonator ID acquisition

unit, an ID of the detonator in the corresponding blast hole

on the basis of the determined location of the blast hole.

In addition, in the receiving of the electromagnetic

wave transmitted from the detonator in the blast hole, the electromagnetic wave having the flickering pattern including identification information of the detonator at the location of the blast hole, the electromagnetic wave being transmitted by the detonator in the blast hole after receiving a command of blasting equipment, may be received.

In addition, in the detecting of the received

electromagnetic wave and derive the electromagnetic wave as

the coordinates, a transmission position and intensity

according to the flickering pattern of the electromagnetic

wave received by using an electromagnetic wave detection

sensor may be recognized and derived as x, y coordinates.

In addition, the method may further include, after the

acquiring of the ID of the detonator in the corresponding

blast hole on the basis of the determined location of the

blast hole, schematizing the detonator information including

the determined location of the blast hole and the acquired ID

of the detonator in the corresponding blast hole, and

outputting the schematized detonator information to a display

means.

In addition, the method may further include, after the

schematizing of the detonator information including the

determined location of the blast hole and the acquired ID of

the detonator in the corresponding blast hole, and the

outputting of the schematized detonator information to the

display means, receiving an input of setting information for setting at least any one of a blasting sequence and a time in milliseconds on the basis of the schematically output detonator information, and transmitting the setting information to the blasting equipment.

Advantageous Effects

According to the present disclosure for achieving the

above objectives, in the device and the method thereof for

determining the detonator information by using the wireless

signal, the electromagnetic wave emitted from the detonator in

the blast hole is detected and derived as the coordinates, and

the location of the blast hole and the ID of the detonator in

the blast hole are determined on the basis of the flickering

pattern of the electromagnetic wave derived as the coordinates,

so that wiring and ID reading work according to the time-in

milliseconds blasting sequence of the detonator is omitted,

whereby there is an effect that the efficiency of blasting

work may be improved and the possibility of human errors may

be maximally reduced.

In addition, in the present disclosure, the detonator

information including the determined location of the blast

hole and the obtained ID of the detonator in the corresponding

blast hole is schematized and output to the display means, and

the input of the setting information for setting at least any

one of the blasting sequence and the time in milliseconds on the basis of the schematically output detonator information is received and transmitted to the blasting equipment, whereby there is another effect that the tasks of collecting detonator

IDs and assigning the time in milliseconds, which are a

significant portion of tunnel and underground blast setting

work, may be simplified.

Description of Drawings

FIG. 1 is a view illustrating a configuration of a

device for determining detonator information by using a

wireless signal according to the present disclosure.

FIG. 2 is a flowchart illustrating a sequence of a

method for determining detonator information by using a

wireless signal according to the present disclosure.

FIG. 3 is a flowchart illustrating a sequence of

operating the detonator information determined in the method

for determining the detonator information by using the

wireless signal according to the present disclosure.

Best Mode

In the present disclosure, various modifications may be

made and various exemplary embodiments may be provided, and

specific exemplary embodiments will be illustrated in the

drawings and described in detail.

However, this is not intended to limit the present

disclosure to a particular disclosed form. On the contrary,

the present disclosure is to be understood to include all

various alternatives, equivalents, and substitutes that may be

included within the idea and technical scope of the present

disclosure. While describing each drawing, similar reference

numerals have been used for similar components.

When a component is described as being "connected",

"coupled", or "linked" to another component, that component

may be directly connected, coupled, or linked to that other

component. However, it should be understood that yet another

component between each of the components may be present. In

contrast, it should be understood that when a component is

referred to as being "directly coupled" or "directly connected"

to another component, there are no intervening components

present.

The terminology used herein is for the purpose of

describing particular exemplary embodiments only and is not

intended to be limiting. As used herein, the singular forms

are intended to include the plural forms as well, unless the

context clearly indicates otherwise. In addition, it will be

further understood that the terms "comprise", "include",

"have", etc. when used in the present application, specify the

presence of stated features, integers, steps, operations,

elements, components, and/or combinations of them but do not preclude the possibility of the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or combinations thereof.

Hereinafter, preferred exemplary embodiments of the

present disclosure will be described in more detail with

reference to the accompanying drawings. Hereinafter, the same

reference numerals are used for the same components in the

drawings, and duplicate descriptions for the same components

are omitted.

First, a system to which a device for determining

detonator information by using a wireless signal according to

the present disclosure is applied largely includes: a

detonator 10 in a blast hole; blasting equipment 20 for

transmitting a blasting command to the detonator; and a device

100 for determining the detonator information by using the

wireless signal of the present disclosure.

FIG. 1 is a view illustrating a configuration of the

device for determining the detonator information by using the

wireless signal according to the present disclosure.

Describing with reference to FIG. 1, the device 100 for

determining the detonator information by using the wireless

signal according to the present disclosure largely includes:

an electromagnetic wave reception unit 110, a coordinate

derivation unit 120, a blast hole position determination unit

130, a detonator ID acquisition unit 140, an information output unit 150, and a setting information transmission unit

160.

The electromagnetic wave reception unit 110 receives an

electromagnetic wave transmitted from a detonator in a blast

hole.

The electromagnetic wave reception unit 110 receives the

electromagnetic wave having a flickering pattern including

identification information of the detonator at a location of

the blast hole, the electromagnetic wave being transmitted by

the detonator in the blast hole after receiving a command of

the blasting equipment. In this case, the blast hole may be

provided with a separate means capable of transferring the

electromagnetic wave, emitted from the detonator in the blast

hole, to the outside. For example, when the electromagnetic

wave is infrared or visible light, the separate means is an

optical fiber, and may be a conductive antenna in other cases,

but is not limited thereto.

The coordinate derivation unit 120 detects the received

electromagnetic wave and derives coordinates.

The coordinate derivation unit 120 recognizes a

transmission position and intensity according to the

flickering pattern of the received electromagnetic wave by

using an electromagnetic wave detection sensor, and derives

the transmission position and intensity as x, y coordinates.

In this case, the electromagnetic wave detection sensor may be a Charge Coupled Device (CCD), Active Electronically Scanned

Array (AESA), and the like, which are provided with integrated

cells for detecting an electromagnetic wave and the like,

including light (i.e., infrared light, visible light, and the

like).

The blast hole location determination unit 130

determines the location of the blast hole on the basis of the

flickering pattern of the electromagnetic wave derived as the

coordinates.

The detonator ID acquisition unit 140 acquires the ID of

the detonator in the blast hole on the basis of the determined

location of the blast hole.

The information output unit 150 schematizes the

detonator information including the determined location of the

blast hole and the obtained ID of the detonator in the

corresponding blast hole, and outputs the schematized

detonator information to a display means.

The setting information transmission unit 160 receives

an input of setting information for setting at least any one

of a blasting sequence and a time in milliseconds on the basis

of the schematically output detonator information, and

transmits the setting information to the blasting equipment.

That is, the setting information transmission unit 160

makes the setting information to be overlaid on a pre-designed

blasting pattern or allows a worker to easily set instantaneous time and time-in-milliseconds intervals on the spot through manipulation by hand, and transmits the setting information to the blasting equipment when the setting information is input in such a way that a time in milliseconds for each detonator is determined. Accordingly, the blasting equipment transmits the time-in-milliseconds information to the corresponding detonator through wired communication.

FIG. 2 is a flowchart illustrating a sequence of a

method for determining detonator information by using a

wireless signal according to the present disclosure.

Describing with reference to FIG. 2, the method of

determining the detonator information by using the wireless

signal according to the present disclosure is to use the

device for determining the detonator information by using the

wireless signal described above, and the duplicate description

below will be omitted.

First, in step S100, an electromagnetic wave transmitted

from a detonator in a blast hole is received.

In step S100, an electromagnetic wave having a

flickering pattern including identification information of a

detonator at a location of a blast hole, the electromagnetic

wave being transmitted by the detonator in the blast hole

after receiving a command of blasting equipment, is received.

Next, in step S110, the received electromagnetic wave is

detected and derived as coordinates.

In step S110, a transmission position and intensity

according to the flickering pattern of the received

electromagnetic wave are recognized by using an

electromagnetic wave detection sensor, and are derived as x, y

coordinates. In this case, the electromagnetic wave detection

sensor may be a Charge Coupled Device (CCD), Active

Electronically Scanned Array (AESA), and the like, which are

integrated cells for detecting an electromagnetic wave and the

like, including light (i.e., infrared light, visible light,

and the like).

Next, in step S120, a location of the blast hole is

determined on the basis of the flickering pattern of the

electromagnetic wave derived as the coordinates.

Next, in step S130, an ID of the detonator in the blast

hole is acquired on the basis of the determined location of

the blast hole.

FIG. 3 is a flowchart illustrating a sequence of

operating detonator information determined in the method for

determining the detonator information by using the wireless

signal according to the present disclosure.

Describing with reference to FIG. 3, a sequence of

operating the detonator information determined in the method

for determining the detonator information by using the

wireless signal according to the present disclosure is as

follows.

First, in step S200, the position of the blast hole is

determined on the basis of the flickering pattern of the

electromagnetic wave derived as the coordinates.

Next, in step S210, the ID of the detonator in the blast

hole is acquired on the basis of the determined location of

the blast hole.

Next, in step S220, the detonator information including

the determined location of the blast hole and the acquired ID

of the detonator in the corresponding blast hole are

schematized and output to the display means.

Next, in step S230, the input of the setting information

for setting at least any one of the blasting sequence and the

time in milliseconds on the basis of the schematically output

detonator information is received and transmitted to the

blasting equipment.

In step S230, the setting information is made to be

overlaid on a pre-designed blasting pattern, or a worker is

allowed to easily set instantaneous time and time-in

milliseconds intervals on the spot through manipulation by

hand, and when the setting information is input in such a way

that a time in milliseconds for each detonator is determined,

the setting information is transmitted to the blasting

equipment.

Accordingly, the blasting equipment transmits the time

in-milliseconds information to the corresponding detonator

through wired communication.

As described above, the functional operation and the

embodiments related to the present subject matter, which are

described in the present specification, may be implemented in

a digital electronic circuit or computer software, firmware,

hardware, or a combination of one or more thereof, including

the structures and structural equivalents thereof, which are

disclosed herein.

The embodiments of the subject matter described herein

may be implemented as one or more computer program products,

i.e., one or more modules related to computer program

instructions encoded on a tangible program medium for

execution by or for controlling the operation of a data

processing device. The tangible program medium may be a radio

wave signal or a computer-readable medium. The radio wave

signal is a signal generated to encode information for

transmission to an appropriate receiver device for execution

by a computer, that is, for example, an artificially generated

signal such as a machine-generated electrical, optical, or

electromagnetic signal. The computer-readable medium may be a

machine-readable storage device, a machine-readable storage

substrate, a memory device, a combination of materials that affect a machine-readable radio wave signal, or a combination of one or more thereof.

A computer program (i.e., also known as a program,

software, software application, a script, or a code) may be

written in any form of any programming language, including

compiled or interpreted language or a priori or procedural

language, and may be deployed in any form, including a

standalone program or module, a component, a subroutine, or

other unit suitable for use in a computer environment.

The computer program does not necessarily correspond to

a file in a file device. The program may be stored in a

single file provided to a requested program, or in multiple

interactive files (e.g., files storing one or more modules,

subprograms, or portions of codes), or in a portion of a file

that stores other programs or data (e.g., one or more scripts

stored within a markup language document).

The computer program may be deployed to be executed on

one computer or multiple computers located at one site or

distributed over a plurality of sites and interconnected by a

communication network.

Additionally, the logic flows and structural block

diagrams described in the present patent document are intended

to describe corresponding functions supported by the disclosed

structural means and corresponding actions and/or specific

methods supported by the disclosed steps, and may also be used to implement corresponding software structures and algorithms and their equivalents.

The processes and logic flows described herein may be

performed by one or more programmable processors executing one

or more computer programs in order to perform functions by

operating on received data and generating outputs.

Processors suitable for the execution of the computer

programs include, for example, both general and special

purpose microprocessors and any one or more processors of any

form of digital computer. In general, the processor will

receive instructions and data from either read-only memory or

random access memory or both.

A key component of a computer is one or more memory

devices for storing instructions and data and a processor for

executing the instructions. In addition, generally, a

computer is configured to perform an operation of receiving

data from one or more mass storage devices for storing data,

e.g., magnetic, magneto-optical disks or optical disks, or

perform an operation of transmitting the data by using the

mass storage devices, or compose or include the data operably

to perform both of the operations. However, the computer is

not required to have such devices.

The present description presents the best mode of the

present disclosure, and provides examples for describing the

present disclosure and for enabling those skilled in the art to make and use the present disclosure. The specification written in this way is not intended to limit the present disclosure to the specific terms presented.

Accordingly, although the present disclosure has been

described in detail with reference to the above-described

examples, those skilled in the art can make modifications,

changes, and deformation to the present examples without

departing from the scope of the present disclosure. In short,

in order to achieve the intended effect of the present

disclosure, it is not necessary to separately include all the

functional blocks shown in the drawings or follow all the

orders shown in the drawings. It should be noted that even

though all the functional blocks are separately included or

all the orders shown in the drawings are followed as they are

shown, the corresponding functional blocks and orders may fall

within the technical scope of the present invention described

in the claims.

Claims (10)

1. A device for determining detonator information by using

a wireless signal, the device comprising:

an electromagnetic wave reception unit configured to

receive an electromagnetic wave transmitted from a detonator in

a blast hole;

a coordinate derivation unit configured to detect the

received electromagnetic wave and derive the electromagnetic

wave as coordinates;

a blast hole location determination unit configured to

determine a location of the blast hole on the basis of a

flickering pattern of the electromagnetic wave derived as the

coordinates; and

a detonator ID acquisition unit configured to acquire an

ID of the detonator in the corresponding blast hole on the

basis of the determined location of the blast hole.

2. The device of claim 1, wherein the electromagnetic wave

reception unit receives the electromagnetic wave having the

flickering pattern comprising identification information of the

detonator at the location of the blast hole, the

electromagnetic wave being transmitted by the detonator in the

blast hole after receiving a command of blasting equipment.

3. The device of claim 1, wherein the coordinate

derivation unit recognizes a transmission position and

intensity according to the flickering pattern of the

electromagnetic wave received by using an electromagnetic wave

detection sensor, and derives the transmission position and the

intensity as x, y coordinates.

4. The device of claim 1, further comprising:

an information output unit configured to schematize the

detonator information comprising the determined location of the

blast hole and the acquired ID of the detonator in the

corresponding blast hole, and output the schematized detonator

information to a display means.

5. The device of claim 4, further comprising:

a setting information transmission unit configured to

receive an input of setting information for setting at least

any one of a blasting sequence and a time in milliseconds on

the basis of the schematically output detonator information,

and transmit the setting information to the blasting equipment.

6. A method for determining detonator information by using

a wireless signal, the method comprising:

receiving, by an electromagnetic wave reception unit, an

electromagnetic wave transmitted from a detonator in a blast hole; detecting, by a coordinate derivation unit, the received electromagnetic wave and deriving the electromagnetic wave as coordinates; determining, by a blast hole location determination unit, a location of the blast hole on the basis of a flickering pattern of the electromagnetic wave derived as the coordinates; and acquiring, by a detonator ID acquisition unit, an ID of the detonator in the corresponding blast hole on the basis of the determined location of the blast hole.

7. The method of claim 6, wherein, in the receiving of the

electromagnetic wave transmitted from the detonator in the

blast hole, the electromagnetic wave having the flickering

pattern comprising identification information of the detonator

at the location of the blast hole, the electromagnetic wave

being transmitted by the detonator in the blast hole after

receiving a command of blasting equipment, is received.

8. The method of claim 6, wherein, in the detecting of the

received electromagnetic wave and derive the electromagnetic

wave as the coordinates, a transmission position and intensity

according to the flickering pattern of the electromagnetic wave

received by using an electromagnetic wave detection sensor is recognized and derived as x, y coordinates.

9. The method of claim 6, further comprising:

after the acquiring of the ID of the detonator in the

corresponding blast hole on the basis of the determined

location of the blast hole,

schematizing the detonator information comprising the

determined location of the blast hole and the acquired ID of

the detonator in the corresponding blast hole, and outputting

the schematized detonator information to a display means.

10. The method of claim 9, further comprising:

after the schematizing of the detonator information

comprising the determined location of the blast hole and the

acquired ID of the detonator in the corresponding blast hole,

and the outputting of the schematized detonator information to

the display means,

receiving an input of setting information for setting at

least any one of a blasting sequence and a time in milliseconds

on the basis of the schematically output detonator information,

and transmitting the setting information to the blasting

equipment.